DE2316540C3 - Circuit for changing the dynamic range of a signal, especially for reducing interference - Google Patents

Description

The invention relates to circuits for coding unc decoding signals that operate similarly to the ir the GB-PS Π 20 541 and 1Z53 031 described

Compressors and expanders and relates in particular to a combined coding-decoding circuit e.g. B. to Noise Reduction.

In such compressors and expanders, a main signal component is transmitted on a main channel from the input to the output, this main channel having the property that it has linearity at least with respect to the dynamic range at every frequency that is within the pi processed by the compressor or expander. nthis lies. The main channel is preferably also linear in another relationship, so that the main component of the signal is proportional to the input signal with respect to its instantaneous values. In the case of a compressor, the main component of the signal is raised and in the case of an expander it is reduced by one or more additional components, which can be derived from one or more rv>«> Uroi-c» n wnitprpn crr> li «» r # »rt uj £> rrie * n Ar »rr» n

Inputs are connected to points of the main channel, and their outputs are connected to one or more: o Combination circuits are connected in the main channel. The combination circuits combine the both components in the corresponding sense in order to bring about an increase or a decrease.

In the case of changes in small signals, the: ^ further components increase or decrease the main components more strongly, so that the further channels have a corresponding gain compared to the main channel. The other channels, however, have strong limiting properties. The characteristic of each of these ν further channels is generally linear up to a limiting threshold which is usually at least an order of magnitude (and preferably two orders of magnitude) below the nominal peak-to-peak signal level. The other js components in this case in no way exceed a level which is greater than approximately a level of the nominal level of the main component reaching from peak to peak. In the case of large signal amplitudes, the increase or decrease with respect to the maximum signal amplitude becomes insignificant, whereby a transmission characteristic is created which has linearity with respect to the dynamic range.

The compressors (encoders) and expanders (decoders) that work according to these principles will be usually (but not necessarily) together in a complete interference elimination system used.

A difficulty that can arise with any compressor and expander is that the signal which is to be processed contains components or constituents which practically block the effect of compression or expansion.

If z. B. the signal is a recurring signal, e.g. B. a video signal, then the frequency spectrum contains essential components at the frame and line repetition frequency and at higher harmonics of the same, z. B. at 25 Hz and its higher harmonics as well as at 15 625 kHz and its harmonics if the picture contains 625 lines and 50 lines per to second The presence of the reason for the fact that the output size of the further channel is limited, so that the f> s interference-clearing effect is blocked. If z. If, for example, a reduction in noise at low frequencies is intended, then there are large signal components at 25 Hz and 50 Hz, etc. and at 15 625 kHz. at 31,250 kHz etc. and the presence of these components brings the limiter properties of the further channel into effect and thereby prevents a significant increase or decrease, which is necessary to carry out the compression and expansion effect.

The invention is therefore based on the object of specifying encoders and decoders that are capable of are, a compression and expansion effect even in the presence of strongly changing signals to cause that have a defined and generally discontinuous frequency spectrum. The encoders and decoders will hereinafter be referred to generally as circuits for changing the dynamic Area of a signal.

According to the invention, this object is achieved in a circuit of the type specified above for changing the

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signal channel, which is a major component of the signal linear in terms of dynamic range from input to output, and with another channel that derives another component of the signal from the main channel and feeds it back to the main channel via a combination circuit, such that the other component either increases or increases the main component in the event of small signal changes weakens, but is limited to a predetermined amplitude which is not greater than about 1/10 des Level of the maximum amplitude of the main component solved by the fact that the further channel facilities having, as a further component of the signal, a difference signal between a signal that is transmitted to a any point of the main channel is tapped, and one opposite that of the main channel at one any point tapped signal form delayed signal.

The main component of the signal is thus combined with the difference signal, the difference signal being the The main component of the signal increases or decreases significantly with changes in small signals, however is limited to a predetermined amplitude which is at most equal to about 1/1 or the maximum amplitude of the Main component is. This avoids overdriving, which occurs during recording processes or cause difficulties in the transmission channel.

It is known from US-PS 36 02 737 to guide the signal frequency over two channels in a circuit arrangement for reducing interference, one of which has the full bandwidth, but the other only transmits the high frequencies. The output signals of the two channels are a subtraction circuit In order to compensate for differences in transit time of the signals, a delay device can be provided in the main channel, which transmits the full bandwidth, so that there are no mutual delays during the subtraction. In the invention, however, in contrast to this, the difference signal is formed between the signal of the main signal and the signal delayed in relation to it

In order to process a repetitive signal, the delay device has a delay time which is equal to a period of the basic repetition frequency or an integral multiple this frequency is assuming that the gain factors with respect to two other channels are essentially equal to each other, components of the fundamental repetition frequency and

their harmonics (collectively referred to as the cancellation frequencies) cancel each other out, i.e. h., they will not appear in the difference signal and therefore will not be the encoder or decoder either To block. As will be explained below, various delays can be used with delay times that are various integer multiples of the delay time mentioned.

In order to avoid the possibility of self-oscillation, is preferred according to the invention an arrangement is used which is referred to in GB-PS 12 53 031 as Type 2 and in which the undelayed or directly traversing further channel with its input in the case of an encoder with the output side of a Combination circuit of the main channel is connected and in the case of the decoder with the input of the Combination circuit is in connection. If the gain of the further channel at this Arrangement is 0.684 below the limiting threshold value, then the amount of the changes Compression or expansion from 0 at the extinction frequency to a maximum of 14.5 dB Frequencies that are in the middle between adjacent cancellation frequencies.

When processing television signals, the delay is, for example, one or more lines, although this requires expensive delay circuits if there is adequate time stability should be achieved. Favorable results can also be obtained by using one or more line delays used for both chrominance and luminance components in the case of an NTSC signal (and delays of two lines for chrominance and one line for luminance in the case of one PAL signals). It is also possible to use closed control loops to adjust the delay times at the correct value, as will be explained further below.

However, the invention is not limited to using delays that coincide with the repetition frequency are related. The delay times can also be short compared to the period be the main information component of a signal, so that it is excluded from the compression and expansion effect. With television systems the delays can range from a fraction of a microsecond to several microseconds. The operation of the invention can be limited to higher frequency components, e.g. B. on Components that typically contain the main noise components, which are complemented by complementary Compression and expansion effects are to be reduced.

The invention will now be explained in more detail with the aid of exemplary embodiments which are illustrated in the drawings explained the

F i g. 1 and 2 show basic circuits of type 1 and type 2 of compressors and expanders Explanation of the invention;

F i g. 3 to 6 show basic circuits of four types of encoders and decoders according to the invention;

F i g. 7 shows a modified form of the circuit of FIG. 6, either for coding or Decoding effect;

F i g. 3 and 9 show more detailed circuitry of the encoder and decoder of FIG. 6;

Figs. 10 and 11 show modified embodiments the F i g. 8 and 9;

FIG. 12A and, ^l 2B show compression and expansion characteristics, which are for television signals in question;

Fig. 13 shows a limiter circuit for achieving a downward turning limiter characteristic;

14 shows a diagram which relates to the circuit in FIG. 13 refers;

Fig. 15 shows a modified embodiment of Fig. 10, in which an automatic gain and / or phase control is applied to the delayed signal;

Fig. 16 is a block diagram of an encoder for use in a color television system for the Color subcarrier area;

Figure 17 is a block diagram of the decoder shown in FIG is complementary to the embodiment of Figure 16;

Figures 18 and 19 show how the circuits are combined can be used to work with different frequency bands separately;

F i g. 20 shows a special embodiment according to FIG. 18 for reducing background noise in a monocromatic television signal;

FIG. 21 shows the coding part of a further exemplary embodiment of FIG. 18 for reducing broadband interference in a color television signal;

Fig. 22 shows frequency bands applicable to Fig. 21;

F i g. Fig. 23 shows a system reversible with decoded color signals Y, t / and Van;

F i g. Figure 24 shows a simple line train delay encoder and decoder;

25 and 26 show further circuits with parallel delay lines, and

Fig. 27 shows a circuit in which simple delays are applied in series.

In order to simplify the illustration, a method of illustration is used below in all drawings used, in which the union of signals as additive mixing (denoted by a + sign) and subtractive union by inverters (denoted by - signs) is used. Be on it pointed out that similar results can be obtained in various other ways using Inverter can also be used at locations other than those shown and / or combination circuits, z. B. Differential amplifiers that actually subtract one signal from another. It is just It is necessary that the closed loops, which are shown as inverting, invert in the overall result. Furthermore, non-inverting loops should also not invert the overall result and the results the combinatorial circuits should remain either additive or subtractive as required is

In Fig. 1 to 6 compressors are designated with C and expanders with E. In Fig. 1 and 2, the compressors serve as encoders and the expanders as decoders. In Fig. 3 to 6, the compression and expansion loops form parts of encoders and decoders. The interrupted connection lines between encoder and decoder are intended to indicate that the coded signals are fed to the decoder either via a recording / reproduction process or via a transmission line or via a signal processing channel which can be referred to as information channel. As described in the aforementioned patents, the overall effect is

therein, the noise "which ivorgang at the recording / Playb ¹ or be inserted in the transmission or in the signal processing channel to reduce an encoder to which a Dekodiei it follows. The letter N in the information channel of F i g. 1 to 6 should indicate that the noise to be reduced is introduced at this point.

In FIGS. 1 to 6, the main channel 10 runs horizontally through a combination circuit II in which with the signal of the main channel, the output variable of a further channel 12 (FIGS. 1 and 2) or 13 (FIG. 3 to 6) is united. More than one combination circuit and other channels can also be used in an encoder or decoder. Further, as shown in Fig. 27, for example, another channel can have various individual signal channels have, the z. B. the same or different delay in the same or different Have parts of the frequency spectrum. In the course of the previous description, for reasons of convenience only referred to one additional channel that provides another output signal, even if there are several other channels with corresponding signals.

The main characteristic of the further channel 12 in FIG. 1 and 2 is that there is an increase (compression effect) or decrease (expansion effect) caused by a signal that has a noticeable effect e.g. at + 1OdB or -1OdB for small Has amplitudes which, however, are limited above a low threshold value so that at Signals with a larger amplitude have no noticeable effect on the output of the further channel exercises, as has already been explained. In the case of the expander, inverters 14 have a subtractive effect Combination. The differences between Type 1 and Type 2 devices are in which Place the other channel 12 receives its input variable.

Type 1 compressor
Type 1 expander

Type 2 compressor

Type 2 expander

Dependent size of the further Channel derived from

Input of the main channel output of the main channel, d. H. Output of the combination circuit 11 Output variable of the main canal, i.e. H. Output size the combination circuit I input of the main channel

Instead of the terms compressor and expander, the more general terms encoders can also be used and decoders are used, in particular in connection with FIG. 3 to 6.

In the F i g. 3 to 6, coding circuits (a) and decoding circuits (b) are provided. The further fto channel 13 has a direct input 15 and a delayed input 16. Examples of the further channel 13 and its various embodiments will now be described. The other channel delays the delayed input signal and uses one or more delay circuits. In the further channel, the difference between the delayed signal and the direct input signals is formed (an inverter 14 for the one signal always being connected upstream). The difference is then limited to a low amplitude. The limiting threshold value is preferably at an amplitude between 1% and 10% of the maximum peak signal amplitude (ie 1 or 2 orders of magnitude smaller than the signal with maximum amplitude). While the limiting property can be sudden or gradual, the output variable of the limiter should gradually assume a horizontal curve as the input signal amplitudes increase (the output variable can even decrease if a limiter with a downward curve is used). The amount which the signal component of the further channel adds to the output signal of the encoder or decoder is preferably less than one tenth of the maximum peak amplitude of the main signal component. In this way, overloads, which can cause difficulties during recording or in the transmission channel, are avoided.

It is desirable to make the arrangement so that the limiters only during a minimum Time proportion are effective, since the noise reduction of the decoder is reduced or even completely is eliminated when the limitation occurs. Use of filters, preferably high pass filters, is for these cases expedient, The use of several different frequency bands for the limiting effect is then usually required. It is possible to reduce the number of bands that are required to achieve a given noise reduction effect by automatically variable filters (those controlled by signals within the encoder or decoder) used instead of fixed filters followed by the limiters. The variable filter can be used at high signal amplitudes cause a narrowing of the band. The frequency band passed by the filter is narrowed to exclude high amplitude signal components, thereby reducing the Output size of the filter is limited. As soon as the large amplitude signal ceases, the pass band becomes of the filter is increased rapidly to allow a larger range of frequencies to pass through and a good one To achieve interference-reducing effect. One can use variable filters with control circuits. In television systems, however, it is useful to have a simple, automatically variable circuit use which is known from GB-PS 11 20 541 as a filter / limiter. Such a circuit includes a Series impedance (which is usually either a capacitor or a parallel resonance trap set on the Carrier frequency is set) and a shunt resistor. The resistance is opposed by poled limiter diodes bridged As can be seen from the cited patent, the diodes conductive and shift the passband of the circuit up (or from the carrier frequency path).

Circuits that either have a normal limiting effect have e.g. B. like diode limiters or the limiting effect with the help of variable Bringing about filtering are referred to below as signal limiters

each of the 8 circuits of FIG. 3 (a) to 6 (b) contains a compressor loop C and an expander loop E (This is the reason that the complete circuits are preferably also used as encoders and decoders

The loop via the direct input 15 brings about the basic coding or decoding effect, which is denoted by the first digit in the following type designation, namely Typel. 1, Type 1.2, T> pe 2.1 and Type 22 according to FIG . 3 to 6. In the case of precisely repeating signals, this effect is canceled out by the complementary effect of the loop over the delay circuit, the type of loop being indicated by the second digit in the type designation above. Cancellation is ineffective with respect to signal components that are not the same in time periods equal to the delay time to which the delayed input signal is subjected.

The effect occurring here can also be viewed in such a way that the opposing effects of the direct and the delayed input variable correspond to a comb filter whose gaps are at frequencies of 1 / i, 2 / t, 3 / f, etc., where t is the delay time The coding or decoding effect is excluded at the notch points. The coding or decoding effect of the type identified by the first digit of the type designation is effective between the notch points. If the signal to be treated has a carrier frequency or other periodic properties, the period of which is equal to f or an integer fraction, then the coding and decoding effect is freed from the periodic effect and this is necessary because the periodic effect otherwise always causes the Limiting effect of the further channel occurs and in this way prevents the coding and decoding, which is necessary for noise suppression, from taking place

If the delay time is short compared to the Is the period of the main component of the signal, there are other ways of looking at the relationships. The main components of the signal are then excluded from the coding or decoding effect, since these components differ during the Change delay time / not significantly. However, higher frequency components are subjected to the coding and decoding action, wherein Noises that typically introduce higher frequencies between encoding and decoding, be decreased. If one takes into account the explanation of the previous paragraph, one can also say that the main components appear in the first notch of the comb filter. Components that are in The higher frequencies of the signal than the main component are then removed from the notches higher order processed

Since type 2 circuits are generally to be preferred, those of type 2.2 of the circuits shown in FIGS. 3 to 6 are used as encoders and decoders according to FIG. 6 preferred. The mode of operation of a type 2.2 circuit is therefore examined in more detail. Since the main channel has a completely linear characteristic, this characteristic can also be designated by operator 1. If in fact the main channel has a gain other than 1, a scaling factor can be added in the following equations. In Fig. 6 the following signals are entered: χ is the coding input signal y is the coding output signal and decoding input signal (ie the signal in the information channel) ζ is the decoding output signal

For the sake of simplicity, only the case of individual delays is considered. Let us consider the characteristics of the further coding channel via the direct input Fi and the characteristics via the delayed input Fi, Fi. where F2 represents the effect of the delay circuit. Let us also consider the characteristics of the further decoding channel via the direct and delay inputs Fj and FiFt.

6a therefore results in y = Af (I-FiF ₂ ) + ^ (F ₁ ), which results in:

χ = y (1 -

-F ₁ F ₂ )

(D

From Fig. 6b results in ζ = y (1 - F ₃ ) -t- Z [F ₃ F *), and from this:

If one now assumes that Fi = F ₃ and Fi = / -i. so it can be shown that the right-hand sides of equations J and 2 are identical, so that results

Z = X

From this it can be seen that the effect of the decoder is actually complementary if the properties of the further channel of the type 12 decoder are the same as the properties of the further channel of the type 22 encoder, so that the coding information signal and the decoding information signal ζ exactly equal to that original input signal is χ

Similar equations can be derived for type 1.1, \ 2 and 2.1 circuits to demonstrate that each encoder is exactly complementary to the decoder.

The foregoing consideration ignores the effect of the decoder on noises generated in the information signal. In order to check this, the amplification of the further channel is denoted by A , the same amplification factor also applying to signals which are fed either via the direct input or the delayed input. The gain factor A is referred to as the unit gain of the main channel and if the gain of the main channel is not exactly = 1, then A = Af / Am, where Af and A _{M are} the gain factors of the further and the main channel, respectively.

The noise voltage at the input of the decoder may be ni and at the output of the decoder /? » Furthermore, let the noise voltage at the output of the decoder z. Zt t (the delay time) before the current time - n »

If the decoder of type 2.2 (Fig. 6b) is used again, the result is

(3)

In a practically implemented system one can assume that the relationship of the circulating Component of the noise in the C-loop of FIG. 6b can be disregarded, since significant components of the circumferential corroded Noise tension can lead to undesirable visible effects. It is therefore indicated the combination of RMS values to investigate. If you assume a white noise, you can get the values

Express nfi - nf from equation 3 in a simplified way as:

- /! ¹ ) = w? (L-Λ) ¹ Hence η} ^ τη = (1 - A) / (\ + A) and i \ Jn, = 1 (1- A) l (\ + A) Type 2.2

When A is the above-mentioned value 0.684, the ratio of no to π is -0.43.

A similar behavior can also be demonstrated for a type 1.1 decoder.

In this case, ι ο

+ Af = π ² , +

(4)

where n _D i is the input noise in the time t before the current time > 5

If one assumes a white noise, then it is

π 2 = n2 and equation 4 simplifies to:

= \ '(\ + Ä ² ) / \ + A Type 1.1

This expression is a minimum when A = 1, where ndnt = I / 1 2, ie a 3 dB reduction in noise.

The derivation of the other terms is not detailed, but the results are as follows to note:

Uv ""; = I / Id + 2 / «) njn, = | 1 - 2 A + 2 A ²

Type 1.2 Type 2.1

3 °

where i gives a minimum at 1/12 when A = '/ 7

F i g. 7 shows a circuit of type 22, which can be switched between the coding in which the switches 17 and 18 are in the R position and the decoding in which the two switches are in the P setting. These settings are designated with R and P because the coding and decoding are typical for recording and playback. The same applies to the representations in FIG. 3 to 5.

F i g. 8 and 9 are block circuit diagrams of an encoder and a decoder of type 22, in which the further channels 13 are shown in more detail. In FIG. 8 the encoder is indicated, the output signal of which is fed to a combination circuit 19 via the direct input 15. The input signal is passed via an inverter 14 and from there via such a delay input 16 to a delay circuit 20 in which it is delayed for the required time, ie by one or more television lines or lines. The delayed signal is fed to the combination circuit 19 via an amplifier 21 and a gain control 22. The gain of the delayed channel is set by the control device 22 to an exact value that corresponds to that of the direct input channel 15, so that the information recurring with a period, f *> which is the reciprocal of the delay time of the delay circuit 20, is withdrawn from the direct channel 15 in the combination circuit 19 with the aid of the delay channel.

The output variable of the combination circuit 19 <«. is passed on via a filter limiter 23 (or optionally also via a number of filter limiters according to FIGS. 25 and 26) and arrives via a Amplifier 25 to an adjusting device 26 ar Regulation of the interference-reducing effect. The further signal component is that from the main channel 10 Supplied components in the combination or mixed circuit ti added

The decoder shown in FIG. 9 restores the original signal, since the further channel 13 corresponds exactly to that of FIG. 8 and the direct and delayed input in the circuit 6b is only transposed and the derivatives given above with regard to the values ζ = χ apply.

Since the channel via the delay input 16 generates a feedback in the circuit of FIG. 9 of less as the unit value becomes the non-periodic Rotate part of the delayed signal as a decreasing infinite series. Both in the coding and in the Decoding circuit are therefore only those .. Signal components that do not match the reciprocal of the Delay time recur, its course influenced. However, interference reduction occurs at any time on, if there are no major changes in the image, be it in the A ^ direction (short delay), in the V-direction (line delay) or on a time scale (line extension and image delay). Of the Limiter 24 only causes a limitation when there are large changes along a line in the case of the short delays or line-to-line changes in the case of line delay or movement in a picture or other picture modifier. in case of Line delays or field delays occur. Such a limitation will not visibly impair the effect of the interference reduction, since it is greater Changes, be it that they occur spatially or temporally. Disturbances that occur during the time of a Remove clogging of the filter limiter in the expansion circuit, hide it, and no significant voltages to reduce the interference deliver.

FIG. 10 shows a modification of the encoder of FIG F i g. 8, in which the individual filter limiter 23 through a filter 27 in the direct input and another Filter 28, which need not necessarily have the same structure, in the delay line is replaced, while a limiter 24 of the mixer circuit 19 is connected downstream. This difference between the filters may be necessary if the bandwidth of the delay circuit 20 is limited. F i g. 11th FIG. 10 shows the complementary decoding circuit which is used in connection with the coding circuit of FIG is used.

The circuits of FIGS. 10 and 11 can be used with delay lines 20 in particular to provide noise reduction over a band typically from 5 kHz to 200 kHz for a television signal is sufficient. This range can be achieved with a simple noise reduction circuit 1 or 2 are not readily taken into account, since signals of large amplitude with line frequency and their multiples are present. In this Case, the filters 27 and 28 are designed as low-pass filters, with a cutoff frequency at z. B. 350 kHz. the Low frequency luminance component of the delay signal is derived from the signal of the direct Signal in the mixer circuit 19, as mentioned above, subtracted. The limiter 24 is an instantaneous one Diode limiter and ideally has a downward turning output characteristic. Optionally can also a filter limiter 23 (as in Fig. 8 and 9)

can be used instead of the filter 24, the frequency characteristic of the further channel by the combined effect of the filters 27 and 28 and the filter limiter 23 is determined

A characteristic curve running downwards is a characteristic curve in which a limitation occurs above a low threshold value which becomes stronger as the signal level approaches higher values F i g. 12A shows the input-output characteristics of the circuit of FIG. 10 in a dB representation. The line 29 represents a linear chyractic characteristic which applies to the main channel 10 and is also effective for the complete circuit at the frequencies that are excluded from the coding effect by the canceling effect of the direct and delay channels. The line 30 represents the compressed characteristic which occurs due to the coding effect at the frequencies that are not excluded, a bend 30A being caused by the threshold of an diode limiter. The curve 31 shows the Störvenninderungskomponente of the signal (output of the further channel) which is a sharp limiting effect has in practice a gradual curve progression 31/4 is achieved (and this is indeed desirable) and the kink 30Λ the curve 30ss is reduced by It should be noted that with large signal changes there is a significant coding overload or a value 32 in the order of magnitude of 1 dB, which is unavoidable when simple diode limiters are used. The desired characteristic is shown in curve 33 and can be obtained in that the characteristic 31 or 31 / t with the aid of the circuit according to FIG. 13 were provided with a downwardly curved characteristic curve section 31 B or 31 C, this figure only showing the limiter 24 of FIGS. 10 and 11 or the filter-limiter arrangement 23 of FIG. 8 and 9 show in detail. The characteristic curve for the decoding is complementary to the compressor characteristic curve and is shown in FIG. 12B

The circuit of Fig. 13 generates corresponding Effects both in coding and in decoding.

The limiter of Figure 13 consists of two oppositely connected diodes 34 which are connected to a resistor 35 and via a Resistor 36 are grounded. When working with a variable bandwidth, resistor 35 becomes like this chosen small that it has no appreciable effect on a change in the capacitor 35/4 and this Capacitor 35 / t together with resistor 36 and diodes 34 form a variable filter. if the point 37 would only have a fixed bias voltage of 0, then the diodes would at a Input voltage of 1.2VoIt, approximately limit. The point 37 is, however, via an inversion amplifier 38, which has a gain below one, provided with a variable bias and the point 37 is therefore instantly influenced in the direction that the clipping level is decreased.

This effect can be explained with reference to FIG. 14 fto , which shows the input-output characteristic curve 39, 40 for the positive limiter diode 34. Curve 41 represents the magnitude of the bias voltage supplied by amplifier 38. This curve has a smaller slope than the unlimited part of the '' 5 characteristic 39, since the gain of the amplifier is less than 1 and z. B. has a gain factor of 'Λ. Since the amplifier 38 inverts, the characteristic curve 41 is subtracted from the characteristic curve 39, 40, so that a downward running characteristic curve 39, 42 results the value 0 at point 44 (which would turn the compressor effect into an expander effect or vice versa). This is prevented by the fact that the output of the amplifier 38 is fed to the point 37 via a resistor 45 which connects the capacitor 46 and the amplifier 47 and in which the signal at the input of the decoupling amplifier is at the same level with the aid of diodes 49 and a Working resistance 50 is limited. If the gain A Wi, then it can be seen that the diodes 49 cause a limitation on the input level V 2 when the diodes 34 a limitation aui cause the input level V.

The lower part of the circuit of FIG. 13 has preferably the same restriction and sieve restriction properties like the top part of the circuit. The lower part of the circuit is completely without effect on the upper part as long as the diodes 34 are not conductive.

The extinguishing effect described between the compressor and expander loops in FIG. 3 to 6 depends on the correct gain that the delay input line versus the direct Channel and that a correct delay time is set. Although it is in In some cases it can be practical to use circuits with correspondingly extended gain and phase stability In other cases it may be desirable to have automatic control of the Provide gain and / or phase with a closed loop. Fig. 15 shows how this can be done in general terms in the case of an encoder of FIG. 10. Similar measures: imitate are also in the decoder of FIG. 11 applicable.

The video signals supplied to the combination circuit 19 are rectified and converted into the Circles 51 and 52 smoothed The rectified signals are with an integration time constant the long is smoothed in comparison with a television line and the output variables of the integrator are compared in a differential amplifier 53. The output voltage of the amplifier on the line 54 controls a voltage-controlled resistor, which is part of a gain control 22 forms and is included in a high gain feedback system, so that only very small Amplitude errors of the delayed signal at the combination circuit 19 can occur.

In order to effect a corresponding phase control, the signals at the two input terminals the combination circuit 19 is fed to a phase comparator 53Λ, the output of which is a Delay in circuit 22 controls.

Figs. 16 and 17 are block diagrams of an encoder or a complementary decoder that is used to process NTSC or PAL chrominance signals can be used in a remote color system.

Matched circles 55 and 56 with bandpass characteristics are matched to the color subcarrier frequency. The delay circuit 20 is typically on 1 (or 2) lines of television in the NTSC system and on 2 lines in the case of the NTSC system Signals set according to the PAL method. The delayed chrominance method is used by the direct

th signal in the combination circuit 19 subtracted after either manually or automatically the Gain and the phases in a circuit 57 have been set.

The phase must be adjusted to reflect the line-to-line phase difference (half period or quarter period) in the subcarrier of the NTSC and PAL system compensated In a similar way, half or fourth period compensations must be made in the case of the Line feed or image delay can be carried out, ι ο

For the line delay, the delay circuit has a delay of 1 line or 2 lines for the simple NTSC signal or a 2 line delay for a PAL signal. The subcarrier frequency is selected in the combination circuit 19 so that this component does not impair the decoding or decoding effect call notches at a distance of 7.8 Fig. 1 which refer to the subcarrier frequency and its inner sidebands are centered.

Components of the luminance signal in the subcarrier area whose frequency spectrum corresponds to that of the Chrominance signals are interleaved, are normally not subtracted in the combination circuit and are of the coding effect in the case of FIG. 16 and the decoding effect in the case of FIG. 17 subject.

In order to be able to treat the different parts of the frequency spectrum separately, separate encoders and decoders can be provided which work either in parallel and / or in series. 18 shows the principle of a series circuit in which an encoder 58 of type 22 is provided on the coding side, followed by a compressor 59 of type 2, while on the decoding side a decoder 60 of type 22 is arranged behind an expander 61 of type 2 is

The further channels of FIG. 18 and FIG. 19 contain filters which define limit bands within which the circles are effective.

In Fig. 19 a device of the type 1.2 is used, which enables a simple Combination or mixing circuit 62 all other channels served On the coding side there are 2 coders 63 and 64 of type 1.2 parallel connection are provided and a compressor 65 of type 2 is connected downstream from them. The encoders 63 and 64 have different delay times and / or different filters in them further course. On the decoding side is a Type 2 expander 66 is provided, followed by two type 1.2 decoders S7 and 68.

Fig. 20 is a block diagram of a broadband interference reduction system for black and white television which is able to reduce interference from 5 kHz to 6 MHz and the detailed circuit of which is shown in FIG. The upper part of Fig. 20 shows the coding circuit, the output variable of which feeds a signal to the input of the decoding circuit, such as is shown in the lower half of the figure, via a transmission channel or a memory, e.g. B. fio a television tape store. The left part of the coding circuit is according to the example of FIG. 10 trained and processes a television signal and the limiter 24 together with the filters 27 and 28 causes them Switching in the frequency band from 5 kHz to 250 kHz fts is effective, the Hedrige cut-off frequency of 5 kHz being formed by the first notch of the comb filter which is centered on the frequency zero. This Frequency band is the lower frequency segment of the Video signal including the line frequency of 15 kHz and its lower harmonics are eliminated by delay line 20, which has a delay of 1 or more lines has, as well as by the combination circuit 19. The right part of the coding circuit consists of one Type 2 compressor, as shown in GB-PS 12 53 031, with two additional channels. These channels contain filters and limiters 69 and 70 which cover the bands from 250 kHz up and down Process 1.6 MHz to 6 MHz. The outputs of the two limiting filters are used by the amplifiers 71 and then to a combination circuit 73 via a gain adjuster 72 the output variable of which is the component of the main channel through a combination circuit 74 is fed. These two further channels therefore correspond to the other channels in FIG GB-PS 11 20 54, although this (as obf, noted) in the Type 2 circuit of the GB-PS i2 5S0? I geschaiiei are and therefore a gain factor less than 1 z. B. have 0.684. These two further channels form two compressors connected in series with the encoder which covers the band from 5 kHz to 250 kHz processed Since the two compressors process much higher frequencies, they are processed by the Line frequency or its essential harmonics are not adversely affected and therefore it is not necessary. To provide means which cancel these frequencies or their harmonics.

The decoding circuit is designed to be completely complementary to the coding circuit Decoding circuit contains the two further channels 69 and 70, which the two high-frequency bands edit and an inversion circuit 14 is provided in front of them. They feed a signal to the combination circuit 74 which is the output of the Adding circuit 73 subtracts the output of the main component from the main channel 10 Combination circuit 74 is applied to the low frequency decoder circuit, the corresponding F i g. 11 is formed

F i g. Fig. 21 is a block diagram of an encoder circuit suitable for color television systems and adjusts Another example of the principle shown in Fig. 18. The circuit in this case has 5 further channels, of which 2 are designed as a delay line, while one at frequencies in the region of the Line frequency works and the others at frequencies work in the area of the color auxiliary carrier. A sixth further channel with delay with respect to the lines of lines can be added to take account of line line frequencies, frame rates and multiples thereof.

F i g. 22 shows the five frequency bands V to Z that are processed in the five further channels. The band V, which ranges from 5 kHz to 250 kHz, is processed by an encoder 75 which includes a delay line 20 which provides a delay of one or more lines. Band W from 250 kHz to 1.6 MHz is processed by a Type 2 compressor which includes a filter and limiter 69. Band X extends from Ifi MHz upwards with a wide notch from 4.0 MHz to 4.9 MHz and is processed by a second Type 2 compressor which includes a filter and limiter 76. The Batid Y ranges from 4.0MHz to 4.9MHz with a sharp

Notch whose center is set on the color subcarrier, which in this case is 4.43 MHz, which corresponds to the European PAL standard. The band Y is processed by another type 2 compressor, which has a filter and limiter 77. If a sixth band U is added then it would operate at frequencies ranging from a fraction of a hertz to the range of a few hundred hertz.

The manner in which the bands W, X and Y are produced corresponds essentially to that in the simultaneously filed German application which corresponds to British patent application 15 485/72.

The narrow band Z, which is set to 4.43 MHz in its center, is determined by a coding circuit 78, which corresponds to that of FIG. 16, with filters 27 and 28 which only cover the band pass from 43 to 4.6 MHz.

The decoding circuit shown in FIG. 21 complementary is obtained by analogy from the drawings mentioned.

In some cases, the encoder 75 can be omitted because of noise reduction in the Band from 5 kHz to 250 kHz is not essential and furthermore the use of a delay line 20 extraordinarily high quality is required in this tape. If this is not observed, the Delay line 20 generate noise components which have the advantage of noise reduction lift.

So far, circuits using only delay lines have been described as examples, but as mentioned above, the delay line 20 in FIG. 8 and 9 can also be replaced by a line train delay, even if e.g. Zt delay circuits of this type with the required stability are still expensive. The line train delay can be a digital delay or a magnetic disk delay. The encoder 63 and decoder 67 of FIG. 19-19 may use line delay while encoder 64 and decoder 68 have line delay. Such a system is advantageous when the different delays allow different types of noise to be dealt with. A line train delay system provides a reduction in interference with respect to time, that is to say it reduces interference which changes from row to row. Although this removes noise, it does not leave a stationary moire or other pattern, such as e.g. B. horizontal bars resulting from a multiple head videotape recorder where one head is not precisely balanced with respect to the remaining heads the y-axis (the vertical axis) performs a line-to-line comparison. Vertical streaks are more favorably handled by compressor-expander channels without delay (e.g. 65 and 66 in Fig. 19) that operate in the X- axis region (in the horizontal region).

It should be noted that the television noise reduction circuit is particularly applicable in cases where the information channel is a television recorder and it is desired to remove or reduce the noise resulting from the recording and reproducing operations. Another important area of application is that the information channel is a standards converter, as will be explained in more detail below. It is also possible to arrange an encoder in front of a television transmission channel and to provide a decoder after the transmission channel in order to reduce interference originating in the transmission channel. Finally, coded signals can be transmitted on the radio path DEPN to receivers which include corresponding decoder. When recording video signals on disks and / or corresponding playback systems, be it optically or mechanically or with other storage devices, it is particularly useful to use the delay for the lines or image changes! with the help of several pick-up devices which scan adjacent tracks of the memory.

Because of the various line offsets that occur from line to line and subcarrier offsets that appear from line to line, e <can be difficult to process an NTSC or PAL signal in encoded form when line delays are used. In any case, it is not easy to divide a coded signal into different frequency bands. However, there is no difficulty, be used wenr so-called baseband signal, unc such a system is shown in Figure 23 on dei coding is the incoming signal is decoded by a decoder 78 and color in the Y, U, V signals for the unc PAL system or the Y, I unc (^ signals for the NTSC system broken down. The decoding also enables signals R, G and B to be obtained. The three signal components are coded in each case (like this word in FIG present invention), by noise reduction encoders 79, 80 and 81 and then recombined into a "color coder 82".

A color decoding egg follows on the decoding side 83 shows an arrangement of noise reduction decoders 84, 85 and 86 followed by a drive encoder 87. the Noise reduction encoders and decoders have the above-mentioned construction, with line delays and / or line train delays, if applicable Addition of compressors and expanders can be used without delay.

F i g. Figure 24 shows a simple form of encoder and decoder for use with circuitry Delay of lines or picture changes. A vidicon camera 88 has one evenly through one Lamp 89 illuminated screen, so that the charge from the screen at a steady speed speed is derived via a resistor 90. In the case* of the encoder, the scanning beam becomes the vidicon roar modulates with the incoming signal and therefore writes the incoming signal over the signal, which: has been recorded in the previous line or frame, depending on dei Decrease caused by the discharge of charge that decoupled with the help of a capacitor 91) Signal therefore represents the difference between the incoming signal and the signal that has traveled by one A line or a picture ago, plus one Component that results from the leakage current. This latter component is thereby extinguished that a mixing circuit 92, the signal coupled out through the capaci tor 91 is fed, as well as eil Signal, which exerted from the output of the main channel

an inversion amplifier 93 and a gain adjuster 94 is derived. Only the difference signal appears at the output of the mixer 92 and this signal is fed via an amplifier 95 to the limiter 24, the output of which is connected to the combination circuit 11. The vidicon therefore causes the delay and also forms the difference signal. A gain factor A of the amplifier 95 determines the gain of the further channel.

The effect on the decoding side is essentially the same, but the beam of the vidicon is modulated by the output of the combination circuit U and the amplifier 95 is an inverting amplifier, so that the limited difference signal is subtracted from the signal of the main channel in the combination circuit 11. The circuit of FIG. 24 is therefore an embodiment according to Type 1.2 and the gain factor A is the factor which is given in the above equation for the interference reduction. The circuits of FIG. 24 can also be used in accordance with FIG. 5 can be modified so that they result in a type 2.1 circuit.

In most embodiments of the invention it is convenient to use a number of signals delayed by t, 2f, etc. to Nt (where t is the repetition and delay period and N is an integral multiple greater than 1). On c ^": ese, the direct signal cooperates line trains V, lines or other repetition periods of the waveform during the previous /.

The principle mentioned is in Fig.25 with reference to a type 2.1 decoder is shown as an exemplary embodiment. They are now / V delay lines 20-1 to 20- / V in parallel with delays of e.g. Legs Line, two lines, three lines, etc. or by 1 line, 2 lines, 3 lines, etc. provided. the delayed input line 16 and the direct input line 15 are according to Fig.5b) switched. The output variables of each delay line are combined in a corresponding combination circuit 96 and are used with the direct Input signal taken from the inverter 14 is combined. The outputs of each of the combination circuits 96 become two filter limiter assemblies 97 and 98 are supplied, the output variables of which are combined in the circuit 99. The output variables All of the circuits 99 are brought together in a circuit 100, the output of which is fed to the combination circuit 11 of the main channel.

2 filter limiters 97, 98 are used for each subchannel of the further channel to reduce the lower and to process higher frequency bands so that the interference reduction continues in one band when blocked by large amplitude components in another band. So can e.g. B. changes in brightness or movements in the image reduce the interference in the band for the Block lower frequencies, but reduce interference in all other higher frequency bands allow.

In the general case of FIG. 25, the further channel contains N subchannels, each of which in turn is split into two (or more, if desired) sub-subchannels. The degrees of amplification of the ΛΖ subchannels do not all need one below

other to be the same, assuming that for optimal interference reduction, the signal of the combination circuits 99 is equal to a 1 / Λ / of that signal is. which is provided by a single delay line 20 in FIG.

In some cases, the effort is too great if one uses delay lines in parallel, and the series arrangement according to FIG. 26 is therefore preferred. This arrangement differs from that of FIG. 25 only in that the delay line 20-1 etc. all have the same delay r, and they are connected in series in such a way that the delay times at their outputs accumulate and t, 2t, 3 / etc. be.

The other channels of FIG. 25 and 26 can also be used in any of the other of the types shown in FIG. 3 to 6 shown Basic circuits for the encoder and decoder be designed.

F i g. 27 shows an embodiment of the further channel in FIG. 26, which in an encoding or decoding according to FIG. 23 z. B. can be used or according to the basic circuit of F i g. 3 to 6. This channel is supposed to work in the range of the time domain of the V-axis or the X-axis. When working towards the X-axis two or more filter limiters 101 are used, the z. B. the circuits 69 and 70 of the F i g. 20 so that a Type 2 compressor or expander is formed when the circuit is designed according to Fig.6. The output variables of the filter limiters are added at point 102 and an output combination circuit 103, the output of which the combination circuit 11 of the main channel. In each case, two filter limiters are provided for the low and high frequency bands, as can be seen in connection with FIG. 25th results.

Delay lines 20-1, 20-2, etc., connected in series are used for the area of the V-axis. provided, each having a delay of 1 line and delayed signals to the combination circuits 19-1, 19-2 and so on. The outputs of these combination circuits become two Filter-limiters 104 supplied, the output variables of which after the combination in the circuits 105 of the Circuit 103 are supplied.

In the area of time interference reduction, the system is similar to that in the area of the V-axis, except that the Delays not by lines but by lines of lines. Only the first delay line 106 is included de ·· Combination circuit 107 shown, as well as two Filter limiter 108 and a combination sound system 105.

In the description of FIGS. 25 to 27 it was assumed that combined filter limiters were used. It is also possible to use the filter effect and to separate the limiter effect, as described e.g. B. in Fig. 10, 11, 15 and 16 and 17 is shown

As mentioned above, the invention can be used to reduce background noise caused by standards converters, wherein a the standards converter upstream encoder has time delays and other parameters that the Norms of the input signal correspond, while a decoder that follows the norm converter has time delays and other parameters that of the Correspond to the norm of the output signal.

16 sheets of drawings

809 615/253

Claims (1)

Patent claims: 1. Circuit for changing the dynamic range of a signal with a main signal channel, * the one main component of the signal linear with respect to the dynamic range from the input transmits to the output, and with another channel that is another component of the signal derives from the main channel and they have a ι ο Combination circuit supplies the main channel again, in such a way that the other component the Main component with small signal changes either increases or weakens, but to one predetermined amplitude is limited, which is not i.s greater than about '/ io of the level of the maximum Amplitude of the main component, characterized in that the further channel has devices which act as a further component of the Signals a reference signa! between a signal, · "> that is tapped at any point on the main channel, and one across from that of the Main channel at any point tapped signal form delayed signal. 2. Circuit according to claim 1, characterized marked ^ 5 shows that the difference signal between a signal tapped at any point on the main channel and a delayed form of the same Signal is formed 3. A circuit according to claim 1, characterized marked \ o characterized in that the difference signal between a signal that is derived from a first to point in the main channel and a delayed form of a signal is formed, wt.ches from a different point of the main channel is tapped (cf. «Figs. 3 and 6). 4. A circuit according to claim 3, characterized in that the further channel (13) has two input signals from points in the main channel different sides of a combination circuit (11) with the help of direct and delayed channels (15, 16), of which the delay channel contains a delay circuit (20), and means (14, 19) which form the difference signal between the signals of the direct channel and the delay channel. 5. A circuit according to claim 4 for coding signals, characterized in that the delay and direct channels with points on the Input side or on the output side of the combination circuit are connected and that the Difference signal increases the main component of the signal (Fig. 3a). 6. A circuit according to claim 4 for decoding signals, characterized in that the .ss Delay and direct channels are connected to points on the output side and input side, respectively, of the combination circuit and that the difference signal reduces the signal of the main component (Fig. 3b). f'f 7. A circuit according to claim 4 for coding signals, characterized in that the delay and direct channels with points on the Output side or the input side of the combination circuit are connected and that the difference f >> reference signal increases the signal of the main component (Fig. 6a). 8. A circuit according to claim 4 for decoding 4 ° 45 50 of a signal, characterized in that the Delay and direct channels are connected to points on the input side and output side, respectively, of the combination circuit and that the Difference signal reduces the signal of the main component (Fig. 6b). 9 _r circuit according to claim 2, characterized in that the further channel decreases an input signal from a point in the main channel and contains a delay and direct channel, both of which are responsive to the input signal and of which the deceleration channel has a delay means for delaying the input signal , while the further channel has means for forming a difference signal between the signal of the direct and the delayed channel 10. A circuit according to claim 2, characterized in that the further channel contains a cathode ray tube (88) that it has means for Scanning of the screen of the tube with a modulated depending on the input signal Having beam, the input signal being tapped from a point in the main channel, and a Raster is generated, the line period of which corresponds to the delay of the input signal, and that a circuit (91) is provided which takes a differential signal from the screen of the tube, the is generated when the scanning beam is passed over the signal written by the previous raster. 11. A circuit according to claim 10, characterized in that the cathode ray tube (88) has a A charge storage tube is a circuit (90) that provides a charge to a screen of the tube and means (89) which make the screen of the tube substantially uniform and illuminate constantly. 12. A circuit according to claim 11, characterized in that means (92) are provided which with the difference signal, which is derived from the screen of the tube, such a proportion of the Combine input signal that cancels the component of the difference signal caused by the Dissipation of the charge is generated during the deceleration. 13. Circuit according to one of claims 9 to 12 for coding a signal, characterized in that the input signal is from a point on the Output side of the combination circuit is derived and that the difference signal raises the main component signal (Fig. 5a). 14. Circuit according to one of claims 9 to 12 for decoding a signal, characterized in that the input signal from a point is tapped on the input side of the combination circuit and that the difference signal the Main component reduced (Fig. 5b). 15. Circuit according to one of claims 9 to 12 for coding a signal, characterized in that the input signal is from a point on the Input side of the combination circuit is derived and that the difference signal raises the main component (F ig. 4a). 16. Circuit according to one of claims 9 to 12 for decoding a signal, characterized in that the input signal is from a point is tapped on the output side of the combination circuit and that the difference signal the Main component reduced (Fig, 4b). 17. Circuit according to one of claims 1 to 16, characterized in that a frequency-selective filter (23) is provided which responds to the difference signal responds, s 18. Circuit according to one of claims 1 to 16, characterized in that the further channel has a filter (35a, 36) on its output side a limiter device (34) connected directly is, so that the passband of the filter at ι ο Occurrence of a signal component is narrowed, which exceeds the intended amplitude to cause a restriction of the difference signal. 19. Circuit according to claim 18, characterized in '5 shows that the limiter device is designed as a diode limiter (34) 20. Circuit according to one of claims 3 to 19, characterized in that the direct and the Delay channel (15,16) frequency-selective filters ^ o that have the same characteristics (27, 28). 21. Circuit according to one of claims S to 19, characterized in that the direct and the Delay channels (15, 16) have frequency-selective filters (27, 28) with different characteristics. - * 5 22. Circuit according to one of claims 3 to 21, characterized in that one of the delay and direct channels (15, 16) has adjusting devices (22) for adjusting the gain, which can be adjusted so that a } ° continuous signal component, whose Period duration equal to the delay of the delay device (20), no component is contributed to the difference signal. 23. A circuit according to claim 22, characterized in that the adjusting device for adjustment of the gain means (51, 52), which from the delay and direct channels (15, 16) derive signals that correspond to the time average that facilities (53) are provided which differentiate these signals in order to split off an error signal, and that means (22) for automatic adjustment of the gain of the delay and direct channel or one of the same depending on the error signal are provided to the Reduce the error signal to zero. 24. A circuit according to claim 22 or 23, characterized in that the device for setting of the gain (22) influences the gain of the delay line (16). 25. Circuit according to one of claims 3 to 24, characterized in that devices (53A) are provided which compare the phases of the related signal components of the delay and direct channel (15, 16) and automatically adjust the delay (20) of the delay line, so that any delay errors are reduced to zero, ^f > ° 26. Circuit according to one of the preceding claims, characterized in that the limiter effect caused by a diode limiter (34). 27. A circuit according to claim 26, characterized marked ⁽ⁱ 5 characterized in that means (38) are provided which are responsive to a signal which is derived from a point of the circuit, to provide a bias for the diode limiter which such a Direction has that the clipping level becomes smaller as the signal level in the circuit increases 28. Circuit according to claim 27, characterized in that that means (49) are provided which the bias signal to a level limit so that the limiting level of the diode limiter (34) does not fall below the value zero can be reduced. 29. Circuit according to one or more of the preceding claims, characterized that a number of further channels (63, 64) are provided, the corresponding difference signals supply which are fed to the individual combination circuits (62) in the main channel. 30. Circuit according to one of claims 1 to 29 for processing television signal components, characterized in that the delay of the delayed signal is substantially> i equal to one or several lines of the remote control signal 31. The circuit of claim 30 for use in a television signal comprising a chrominance subcarrier component contains, characterized in that means are provided to fine-tune the delay to compensate for subcarrier warpage. 32. Circuit according to one of claims 1 to 29, for processing television signal components, characterized in that delaying substantially a delayed form of the signal is equal to one or more lines of the television signal. 33. A circuit according to claim 32, characterized in that the devices for fine adjustment the line train delay are provided. 34. Circuit according to claims 32 or 33, characterized in that the line train delay device is provided with a digital delay device. .> 5. Circuit according to claims 32 or 33, characterized in that the line train delay is determined by deriving a direct and a delayed signal from various heads of a video disk recorder will. 36. Circuit according to one of claims 1 to 29 for processing television signal components, characterized in that the delay of the delayed form of the signal is equal to a small one Is a fraction of a line period of the television signal. 37. Circuit according to one or more of claims 30 to 35, characterized in that a number of circuits (79, 80, 81) for processing decoded components of a Color television signals are provided that a color decoder (78) feeds these circuits and that a color encoder (82) is based on the output variables of the different connections. 38. Circuit according to one or more of claims 30 to 37, characterized in that * the circuit (63) is connected in series and / or in parallel with at least one further circuit (64) which corresponds to one of claims 30 to 37 and / or with at least one compressor or Expanders (65 or 66), each circuit including filters operating on different parts of the television signal frequency band speak to. 39. A circuit according to one or more of claims 30 to 38, characterized in that a coding circuit is connected upstream of a television standard converter and that a decoding circuit follows a standard converter, the delay times of the coding or decoding circuit corresponding to the input and output standards of the standard converter. 40. Circuit according to one of claims 3 to 39, characterized in that the delay channel contains a number N of delay devices (20-1, 20-2, 20-3) which deliver ΛΖ signals which are delayed by times t to Nt and that the further channel contains means (14,96) which form the differences between the signals formed by the direct channel and the A / signals corresponding to the various delays. 41. A circuit according to claim 40, characterized in that the delay channel contains N delay devices in series which each have a delay of t and that the N signals are taken from the outputs of the N delay circuits. 42. Circuit according to claim 40 or 41, characterized in that the delay channel contains a first group of delay circuits (20-1, 20-2) which deliver signals which are delayed by multiples of a television scanning line and a second group of delay devices (106 ), which deliver signals that are delayed by a multiple of a television line. 43. Circuit according to one or more of the preceding claims, characterized in that that a number of limiter devices (97, 98) are provided, which on different Address areas of the frequency band difference signal. 44. A circuit for reducing interference with a circuit arrangement according to claim 1, which can be switched from an encoding state to a decoding state, characterized in that the further channel (13) derives two input signals from points of the main channel on different sides of the combination circuit (11), with the aid of direct and delay channels (15, 16), of which the delay channel contains a delay device (20), and in that devices (14, 19) are provided which form the difference signal between the signals supplied by the direct and the delay channel and further characterized in that in the case of the coding operation the delaying and direct channels are connected to points on opposite sides of the combination circuit (11) and the difference signal emphasizes the main component, while in the decoding operation the delay and direct channels are opposite with the dots on top of one another r opposite sides of the combination circuit are connected and the difference signal reduces the main component 45. Noise reduction circuit with a circuit according to claim 1, which can be switched between a coding mode and a decoding mode, characterized in that the further channel takes an input signal from one point of the main channel and contains delay and direct channels, both of which respond to the input signal of which the delay channel has a delay device which delays the input signal, and in which the further channel has devices which form a difference signal between the signals generated by the direct and the delay channel, and further characterized in that in the coding operation the point on the one side of the combination circuit (11) and the difference signal increases the main component, while in the decoding operation the point is on the opposite side of the combination circuit and the difference signal decreases the main component. 46. interference reduction circuit with a coding circuit according to claim 1 and with a decoding ^ chsltu "" nsch Ans ^ ru ^ h t and bc flpr pm Transmission channel is provided, which signals from the first circuit to the second circuit transmits, characterized in that the further channel (13) of each of the circuits has two input signals taps from points in the main channel that are on opposite sides of the combination scarf device (11) lie, with the help of a direct and a delay channel (15, 16), of which the Vvi delay channel comprises a delay device (20) and contains means (14, 19) which form the difference signal between the signals of the direct and the delay channel, and further characterized in that in the coding mode, the delay and direct Channels connected to points on opposite sides of the combination circuit (11) and the difference signal increases the main component, while in the decoding operation the Delay and direct channels in opposite ways with the points on either side of the combination circuit are connected and the difference signal reduces the main component. 47. noise reduction circuit with a coding circuit according to claim 1 and with a decoding circuit according to claim 1 and with an information channel which transmits signals from the first circuit to a second circuit, characterized in that the further channel of each of the two circuits receives an input signal from a point in the main channel decreases and contains delay and direct channels, both of which respond to the input signal and from d ..: en the delay channel has a delay device for delaying the input channel and in which the further channel has means for forming a difference signal between those from the direct and contains signals supplied to the delay channel, and further characterized in that in the coding mode the point is on one side of the combination circuit (11) and the difference signal increases the main component, while in the decoding mode the point is on the opposite side of the combination circuit The main component is reduced by the difference signal.